RU2351895C2 - Method of determination of individual linear measuring weight - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: invention can be used for estimate immediately in field requirements with high degree of objectivity and reliability of effects of individual linear measurings apart more than 1353 metres. Method provides carrying out of additional measurings on control marks the test objects with three horizontal marks in the form of mirrors. The central control mark is combined with the sighting target and the electronic distance metre; measure lengths of collimating rays L₁, L₂, L to control marks the test objects with t_L accuracy. On the observed data, calculate distance between centres of the extreme marks under the formula b_pract=(2L₁ ²+2L₂ ²-4L²)^1/2 and the obtained value is compared to its test object fixed value b_testingobj. Weight of E_L individual linear measuring is estimated under relation of absolute value of discrepancy Δ_b =\b_testingobj-b_pract.\ to theoretical accuracy of the linear measuring t_L, counting its numerical value under the formula E_L=(1+Δ_b/t_L)^-1.

EFFECT: expansion of scope and increase of objectivity and reliability of effects.

2 cl, 1 dwg

Description

The invention relates to geodetic measuring equipment and can be used to evaluate directly in the field the individual results of linear measurements in the production of geodetic works.

There is a method of determining the weight of a single geodetic measurement in the observer-device-sighting beam-sighting target, providing for additional measurements on a world scale that fixes a change in the geometric dimensions of separately sighted objects with a change in the length of the sighting beam when observed under optimal conditions with a maximum resolution of the armed eye observer, and the calculation of the numerical value as the ratio of R _n / R _o , where R _n - the length of the target beam to the target; R _o is the result of an additional measurement (description of RU 2234061, IPC ⁷ G01C 15/06, 2003.03.31).

The known method can be used only in the production of high-precision leveling, which limits the scope of its application.

The means used in the known method for obtaining comparison results and the selection of a criterion in calculating the numerical value of the weight of a single measurement do not allow to evaluate the current state of all components of the main linear measurement that affect the uniformity of single measurements, including the physiological state of the observer, the technical condition of the geodetic instrument, the state of the medium in which the target beam passes, the technical condition of the target. This reduces the accuracy of assessing confidence in single linear measurement results.

The objective of the invention is the development of a universal method for determining the weight of a single linear measurement.

The technical result from the use of the method is the expansion of the scope and increase the objectivity and reliability of the results.

The technical result is achieved by the fact that in the method for determining the weight of a single linear measurement in the observer - device - target beam - target, providing for additional measurements on control marks of the worlds and calculation of the numerical value of weight, for measurements use the world with three horizontal marks in the form of reflectors , the center of which is combined with the target and the sighting reticule rays measured length L _1, L _2, L respectively to the extreme and moderate control marks worlds, and the weight of the unit lineynog E _L measurement is judged by reference to the absolute value of the difference distance b between the centers of the extreme _worlds control marks worlds and its practical value

b _practice , calculated according to the results of measurements from the expression b _practical = (2L ₁ ² + 2L ₂ ² -4L ² ) ^1/2 , while determining the numerical value of the weight according to the dependence: E _l = (1 + Δ _b / t _L ) ^{- 1}

where Δ _b = | b _worlds -b _prakt |, m; t _L - theoretical accuracy of linear measurement, m. As a device, a light-range finder can be used.

The drawing shows (top view) of the world with control marks and a diagram of additional measurements.

The world includes control marks B ₁ B ₂ B ₃ in the form of reflectors installed on a horizontal bar with the placement of extreme B ₁ , B ₃ relative to the central B ₂ at equal fixed distances b ₁ = b ₂ .

To implement the method, the central control mark B _{2 is} combined with a target (not shown) and direct field measurements with an accuracy of m _{s with a} light range finder (not shown) from position O measure the length of the target beams L ₁ , L ₂ , L, respectively, to the extreme B ₁ , B ₃ and middle In ₂ control marks worlds. According to the measurement results, using the median property ОВ _{2 of the} triangle ΔOB ₁ В _3, calculate the side length | B ₁ В ₃ | corresponding to the distance b _prac between the centers of the marks B ₁ B ₃ , using the formula b _prak = (2L ₁ ² + 2L ₂ ² - 4L ² ) ^1/2 and the found value is compared with its fixed value b _worlds = b = b ₁ + b ₂ . The weight of a single linear measurement E _L is judged by the ratio of the absolute value of the difference Δ _b = | b _worlds -b _prac | to the theoretical accuracy of the linear measurement of t _L , calculated as a function of the measured values (parameters of the world). The numerical value of E _{L is} calculated by the formula E _L = (1 + Δ _b / t _L ) ^-1 .

The method allows directly in the field to evaluate with a high degree of objectivity and reliability the results of single linear measurements of the target at a distance of more than 1353 meters.

The table below shows examples of the results of additional linear measurements performed to calculate the weight of a single linear measurement performed using the ST-5 “Gloss” light range finder with a distance measurement accuracy of m _s = 0.007 + 0.004S and a reference world with a distance between the extreme reflectors of 1.602 m.

Table Measurement number L, m t _L L ₁ L ₂ b _practice b _worlds Δ _b , mm E _l abs, m relates. 01 136,482 8 1: 18087 136,484 136,484 1,5927 1,6020 -9 0.81 02 138,338 8 1: 18315 138,340 138,340 1,5956 1,6020 -6 1.17 03 142,332 8 1: 18804 142,334 142,334 1,5982 1,6020 -four 1.97 04 145,047 8 1: 19135 145,049 145,049 1,6111 1,6020 9 0.84 05 161,890 8 1: 21169 161,892 161,892 1,6074 1,6020 5 1.41 06 168,342 8 1: 21938 168,344 168,344 1,5964 1,6020 -6 1.37 07 177,485 8 1: 23020 177,487 177,487 1,6082 1,6020 6 1.24 08 281,529 8 1: 34645 281,530 281,530 1,6010 1,6020 -one 8.31 09 283,539 8 1: 34858 283,540 283,540 1,5891 1,6020 -13 0.63 10 287,379 8 1: 35263 287,380 287,380 1,5981 1,6020 -four 2.07 eleven 298,372 8 1: 36416 298,373 298,373 1,5811 1,6020 -21 0.39 12 306,680 8 1: 37279 306,681 306,681 1,5850 1,6020 -17 0.48 13 315,823 8 1: 38220 315,824 315,824 1,6138 1,6020 12 0.70 fourteen 319,817 8 1: 38629 319,818 319,818 1,6017 1,6020 0 26.45 fifteen 423,861 9 1: 48745 423,862 423,862 1,5741 1,6020 -28 0.31 16 443,419 9 1: 50540 443,420 443,420 1,5887 1,6020 -13 0.66 17 451,881 9 1: 51306 451,882 451,882 1,5861 1,6020 -16 0.55 eighteen 458,155 9 1: 51871 458,156 458,156 1,5726 1,6020 -29 0.30 19 464,864 9 1: 52471 464,865 464,865 1,6069 1,6020 5 1.81 twenty 484,165 9 1: 54177 484,166 484,166 1,5915 1,6020 -eleven 0.85 21 585,751 9 1: 62694 585,752 585,752 1,6130 1,6020 eleven 0.85 22 590,219 9 1: 63052 590,219 590,220 1,6081 1,6020 6 1,52 23 601,346 9 1: 63936 601,346 601,347 1,5802 1,6020 -22 0.43 24 603,202 9 1: 64083 603,203 603,202 1,5733 1,6020 -29 0.33 25 626,497 10 1: 65906 626,498 626,497 1,5916 1,6020 -10 0.91 26 739,684 10 1: 74275 739,684 739,684 1,6030 1,6020 one 10.14 27 763,236 10 1: 75922 763,236 763,236 1,6096 1,6020 8 1.32 28 767,704 10 1: 76231 767,704 767,704 1.6377 1,6020 36 0.28 29th 771,544 10 1: 76495 771,544 771,544 1.5561 1,6020 -46 0.22 thirty 901,574 eleven 1: 85004 901,574 901,574 1,5429 1,6020 -59 0.18 31 908,025 eleven 1: 85404 908,025 908,025 1,5804 1,6020 -22 0.49 32 910,036 eleven 1: 85529 910,036 910,036 1,6236 1,6020 22 0.49 33 1,055,083 eleven 1: 94033 1,055,083 1,055,083 1,5448 1,6020 -57 0.20 34 1069,916 eleven 1: 94854 1069,916 1069,916 1,6080 1,6020 6 1.88 35 1191,565 12 1: 101270 1191,565 1191,565 1,6060 1,6020 four 2.96 36 1353,455 12 1: 109028 1353,455 1353,455 1,6076 1,6020 6 2.21

Claims (2)

1. The method of determining the weight of a single linear measurement in the observer - device - target beam - target, providing for additional measurements on control marks of the worlds and calculation of the numerical value of the weight, characterized in that for measurements they use the world with three horizontal marks in the form of reflectors, the central of which is combined with the target, and the lengths of the target rays L ₁ , L ₂ , L are measured to the extreme and central control marks of the world, respectively, and judging by the weight of a single linear measurement E _L judging t by the absolute value of the difference in the reference distance b _worlds between the centers of the extreme control marks of the worlds and its practical value b _practical calculated from the results of the expression b _practical = (2L ₁ ² + 2L ₂ ² -4L ² ) ^1/2 , determining numerical value of weight according to
E _L = (1 + Δ _b / t _L ) ^-1 ,
where Δ _b = | b _worlds -b _prakt |, m,
t _L - theoretical accuracy of linear measurement, m 2. The method according to claim 1, characterized in that as a device using a light range finder.